Dynamoelectric machine



July 20, 1965 H. c. KAEDING DYNAMOELECTRIC MACHINE Filed Sept. 28, 1960 United States Patent O 3,196,297 DYNAMELEQTREC MACHINE Hugo C. lined-ing, Fort Wayne, ind., assignor to General Electric Company, a corporation of New Yori: Filed Sept. 2S, 19nd, er. No. 53354 3 Claims. (Ci. 3io-53) My invention relates to dynamoelectric machines and more particularly to small motors for use in applications where enclosed electrical components are desired.

ln certain applications for small electric motors, it is desirable, if not necessary, that the electrical components, i.e., the windings and their connections, be enclosed from the surrounding atmosphere. For example, fractional horsepower motors are used today in many domestic refrigerators to drive air circulating fans, and both to protect the motor itself and to avoid hazard, it is necessary that the motor windings be effectively separated from the surrounding atmosphere. Considerable condensation of moisture occurs within the refrigerator and since the condensate may drip or otherwise come into contact with the motor, a waterproof casing should be provided for the windings to prevent shorting or grounding by the condensate. Also, since any electrical winding is liable to failure over an extended period of time, efrigerators being used upwards of 15 to 20 ears, the motor windings should be encased to prevent the escape of molten copper if failure should occur after years of service. Obviously, if molten copper could escape into the refrigerator, a considerable fire and personal hazard would be created. The same considerations hold true for any ilames or sparks occurring upon motor failure, which should also be prevent-ed from escaping into the surrounding environment.

The solution heretofore generally used by fractional horsepower motor manufacturers for these applications where the electrical components of the motor must be eparated from the surrounding atmosphere is to encase the motor completely with a metal enclosure. In other words, the motor housing surrounds the rotor and the stator with no openings whatsoever except for the output shaft. These motors are known as totally enclosed motors and they do result in acceptable protection of the windings and elimination of hazard upon winding failure. But they are quite expensive as compared to au open motor and in addition they have several inherent disadvantages. Their size and bulk is increased as cornpared to an open motor, which sometimes makes them more diiiicult to use where space is at a premium. Also, and probably most important, the normal ventilation system for open motors wherein the heat generated in the windings is dissipated to a stream of air passed through the motor cannot be used. With the lack of adequate ventilation, the motor temperature necessarily rises and consequently the life of the winding insulation is adversely effected. Also, the lubrication properties of the oil supplied to the shaft bearingsfare reduced due to the higher temperature of operation.

Accordingly, it is a principal object of my invention to provide a new and improved motor for use in application where enclosed electrical components are desired, wherein only the windings are enclosed as contrasted to the entire motor.

It is another object of my invention to provide a new ICC and improved motor wherein the windings are effectively protected from moisture and from the escape of molten copper and llame upon failure, but yet the motor is directly ventilated to the surrounding atmosphere and is not increased in size or bulk.

A further object of my invention is to provide a new and improved motor for use in applications requiring enclosed electrical components, which is cheaper to manufacture than a totally enclosed motor of equivalent output.

Briefly stated, in accordance with one aspect of my invention, I provide an electric motor including a rotor and a stator. The stator carries the energizing winding of the motor, random wound in the illustrated embodiment, which is formed of a number of contiguous turns of metallic wire having an adherent coating of insulating material. This coating `serves to insulate the various turns of the winding from each other and is selected to have a predictable melting or failure temperature. Both to protect the winding and to render it fail safe, l enclose it within an imperforate covering of protective material, which is formed over the exposed outer surface of the winding in a generally nonpenetrating relation thereto. By my invention, this imperforate covering is also selected to have a predictable i elting point, and it is so arranged that it is not affected by heat within the winding as readily as is the insulating coating on the wire itself. Thus, in the event of a failure in the winding, the wire coating is melted to accelerate a complete failure of the motor before the outer protective covering of the winding is affected. Thereby, the outer covering is effective to prevent the escape of molten copper and any accompanying sparks or flame, and the motor is suitable for use in application requiring fail-safe electrical components Without a complete metal housing for the motor being required. During normal operation of the motor, the imperforate outer covering for the winding is effective to prevent the entry of moisture into the winding and thereby aids in avoiding winding failure in the first place.

rturning now to another aspect of my invention, the above described arrangement of the windings allows the elimination of the over-al1 motor casing so far as the protection of the winding is concerned. However, if the best advantage is to be made of this protected winding arrangement, the motor lubrication system must also be constructed so that there is no need for a metal casing surrounding the motor. ln other words, the lubrication system should provide reliable lubrication for the shaft bearings under adverse moisture conditions without an over-all motor enclosure being required. Also, the system should be capable of providing bearing lubrication over a long period of years without reoiling, since the motors may be used on applications such as refrigerators where the purchaser expects maintenance free service for a period of 15 to 20 years. The elimination for the need for reoiling also will allow the motor to be positioned in locations which are relatively inaccessible once the refrigerator or other end product is completed.

Therefore, it is another object of my invention to provide an improved lubrication system which may be advantageously used with my protected winding arrangement to produce a moisture proof, fail-safe motor.

Another object of my invention is to provide a new and improved enclosed lubrication system for small dynamoelectric machines, which will provide reliable service for a long period of years without reoiling.

in carrying out this aspect of my invention, now disclosed and claimed in my co-pending divisional application Serial No. 590,158, filed August 17, 1964, I provide a bearing assembly which includes a bearing membei' for journaling the rotor shaft. A. pad of lubricant impregnated material is disposed adjacent the bearing member for feeding lubricant to the shaft and to make the system suitable for use in applications requiring enclosed components, a substantially imperforate casing is provided around the pad. The casing encloses the pad except for the region of contact between the bearing member and the pad and it both protects the pad and prevents the evaporation of lubricant therefrom. It is desirable that atmospheric pressure be maintained in the pad to produce an even flow of lubricant from the pad to the bearing over an extended period of time, and for that purpose the casing includes a breather opening in one Wall thereof. Further, at least one internally protruding rib is formed on the same wall of the casing to space the pad from that wall whereby any drops of lubricant forming on the exterior of the pad may freely move to another portion of the pad and be reabsorbed for future use on the bearing member. An internal flange formed around the breather opening prevents such drops from escaping through the opening, and the end result of the entire arrangement is that the bearing member is effectively lubricated for extended periods of time with no reoiling of the pad being required.

The subject matter which l regard as my invention is particularly pointed out and distinctly claimed in the concluding portion of this specification. My invention, however, both as to organization and method :of operation, together with further objects and advantages thereof, may be best uderstood by reference to the following description taken in conjunction with thel accompanying drawing in which:

FIG. 1 is an elevational view of a small electric motor which embodies my invention in one form thereof, the view being partially broken away to show details;

FIG. 2 is a side View, partially in section, of the motor of FlG. 1.

FG. 3 is an enlarged sectional view taken along the line 3 3 of FIG. 1 and illustrating the terminal arrangement incorporated in the motor;

FIG. 4 is an enlarged fragmentary view illustrating one of the bearing assemblies utilized in the motor; and

FIG. 5 is a cross sectional View taken on the line 5 5 of FiG. 1 and `showing the stator yoke section and the energizing winding tof the motor.

Referring now to the drawing, I have shown therein an electric motor 1 which embodies my invention in one form thereof. The motor ll is of the shaded pole type and it includes a stat-or 2 and a rotor 3. The rotor 3 is positioned between a pair of oppositely disposed pole faces provided on the stator, one of the pole faces being shown at 4, and the rotor is activated during operation by means of the magnetic flux passing between these pole faces. Suitable shading coils are provided at the trailing ends of the stator pole faces to provide starting torque and to aid in producing running torque. For example, the shading coils for the pole face 4 may comprise a pair of copper rings such as are indicated at 5 :and it will be understood that similar coils are mounted diametrically opposite on the other pole face.

The magnetic flux for exciting the rotor 3 is provided by an electrical winding or coil 6 which is mounted on a yoke section or winding leg '7 `of the stator. As is best shown in FIG. 1, the winding leg 7 is positioned between and in tight engagement with depending legs 3 and 9 of the stator and these legs serve to complete the flux path between the winding legs 'and the pole faces.

`As is best seen in FIGS. 2 and 5, both the winding leg or yoke section 7 and the main portion of the stator are formed of a plurality of stacked laminations of magnetic material. The winding leg 7 is formed Separately from the rest of the stator and is pressed into position between the legs S and 9 after the coil d is wound thereon. The press tit between the winding leg '7 and the depending legs S and 9 is enough in itself to keep the winding leg in place with no additional securement being required. It will be understood that the rotor 3 is also formed of a plurality of stacked laminations of magnetic material with a squirrel cage winding of conductive material being provided in slots forme therein.

lt will be noted from the drawing that Vthe motor 1 does not include an over-all protective metal housing or casing. Nonetheless, by my invention, the motor is so constructed and arranged that it is suitable for use in applications requiring enclosed electrical components. To this end, the winding 6 is arranged so that it is both fail-safe and moisture proof. Specifically, the winding 6 is provided with an outer protective covering l@ and this covering 1d is so selected and formed that it prevents the entry `of moisture into the winding and also contains any sparks or flames which might occur upon failure of the winding.

Taking first the fail-safe feature of the invention, this depends upon a predetermined relationship between the wire of the winding and the material of the outer protective covering it). The wire of the winding ti cornprises metallic wire having adherent insulating coating and this insulating coating is effective to insulate various turns of the winding from each other. in other words, the winding 6 is formed of the type of wire known in the motor industry as magnet wire. The type of magj net wire used in the winding is very important to my invention. Specifically, the magnet wire must be so selected that its insulation has a predictable melting or failure point in terms of temperature, which in my preferred embodiment is lower than the melting or failure point of the material forming the outer covering l@ of the winding. In my preferred embodiment, l utilize a magnet wire having a two layer insulating coating, the inner layer being formed of polyurethane and the outer coating being formed of nylon. The polyurethane inner coating gives a predictable melting point for the wire insulation between C. to 225 C. and also renders it moisture resistant, while the outer nylon coating gives mechanical protection such as scrape resistance and crack resistance to the wire. A commerically available wire of this type which is suitable for use in my invention is the Nyleze wire produced by the Phelps Dodge Copper Products Corporation.

The outer covering 1f) of the coil is also selected to a predictable melting or failure point, and in particular it is selected and arranged so that it will not be affected immediately by an over-temperature condition within the coil 6. Thus, if a failure occurs within the coil, the heat created by the failure affects the insulation of the magnet wire before it affects the outer covering lil. ln other words, it accelerates the failure of the magnet wire without causing the outercovering lil to fail. Thus, what may be initially only a small ground or short within the winding will rapidly lincrease to a fault of major magnitude. This fault as it increases in magnitude will, of course, draw increasing current through the line and will blow the line fuse or trip the line breaker or generate enough local heat to cause the wire to sever before the outer coating 10 is melted. f

Before turning to the material and formation of the covering lil, it will be'noted that in the selection of the magnet wire not only is the melting point ofthe wire insulation of importance but also the products formed by the melting or decomposition are important. in particular, the insulation of magnet wire should be selectedV so that itzwill give a minimumof gases upon melting. This will, of course, avoid internal pressures in the winding such as might rupture the outer covering l?. Also what gases are given oil should not be combustible or toxic. This is, of course, desirable to avoid both a tire and a personnel hazard upon the winding failure.

Referring now to the outer protective covering lil, this covering must not melt or fail upon an over-heating condition in the winding as quickly as the insulating coating on the magnet wire. Since the covering lil is exterior to the winding, the magnet wire of the winding is necessarily heated more quickly than the covering when excess heating occurs in the winding. ln other words, there is an inherent t ermal time delay in the heating of the covering which means that its temperature rise will lag behind the internal temperature of the windinU. Thus, even if the material of the outer covering does not have a higher absolute melting or failure point than the insulating coating on the magnet wire, the wire coating will be heated more quickly and will fail before the covering l@ in the event of a winding failure.

ln the illustrated embodiment, to insure further than the covering lil will not melt as quickly as the insulation on the magnet wire, l have used a resinous material for the covering which itself has a higher absolute melting point than the magnet wire insulation. Specifically, in the illustrated embodiment, the covering lil is formed of a thermosetting resin and in particular of an epoxy resin. rhis resin of the illustrated embodiment is so selected that it will not melt or fail until an internal hot spot t perature or" about 406 C. is reached in the winding o. Will this 450" C. hot spot temperature required within the winding before the covering will melt, it will not fail as soon as the magnet wire and thereby it will contain any flame or combustible products resulting from a failure within vthe winding long enough for the line fuse of the motor to be blown or for the wire to break apart within the winding. A material which l have used for forming the coil is the Corvel Epoxy EXP-24A which is available from National Polymer Products, lne. Depending upon degree of cure, this material has an absolute melting point of 250 C. or higher for the transient heat conditions which are encountered during motor failure.

The resinous coating l@ is formed around the coil 6 after the coil itself is wound on the winding leg or yoke section '7. The resin for forming the coating is deposited over the coil and then is cured in place so as to form an imperorate covering or casing over the coil in intimate contact therewith. Although the resin may be deposited and cured in any suitable manner, one Way in which it may be done is to dip the coil in a luidized bed of the uncured resin powder while at the same time passing a llt-C. current through the winding. The powder as it is deposited on the coil by the fluir 'Zed bed is melted by the heat in tie coil itself so that it adheres to the coil, whereby after curing in an oven it forms a unirorrn irnperiorate and void free covering over the coil in intimate Contact therewith.

As mentioned above, the covering must be such that it will not allow the escape of llame or sparks from the winding or coil 6 upon failure and also for protection of the motor it should be water tight. Since the covering is imperforate, it will not allow water or llame to pass through it, but in addition, it must make a water impervious and llame resistant joint to the winding leg at the end of the coil. ln my preferred embodiment, this is accom ished by bonding the covering lill to the ground insulation on the winding leg itself. As is best shown in lilG. 5, the winding leg includes a covering of insulating material l over the entire area on which the coil 6 is wound. This layer of integral insulation may be placed on the winding leg in any suitable manner as by a lluidized bed process andtin the illustrated embodiment it comprises a mica illed epoxy resin with a suitable hardener such as an amine hardener. ln particular, this integral insulation is chosen to be compatible with the material of the covering El@ so that the covering will bond to it when it is formed over the coil 7. This bond which may be automatically formed by the resinous material itself as the covering lil is formed, is effective to prevent water from leaking into the coil alonf7 the winding leg and to prevent the escape of llame upon any failure of the coil.

ln order to provide complete moisture proofing and fail-safe characteristics the lead-in connections to the winding or coil 6 should also be llame and moisture proof. Before turning to these lead in connections, one additional feature of the coil itself should be noted. Referring now to FlG. l, it will be noted that the coil is random wound instead of being form wound. In other words, instead of the magnet wire being wound on the yoke section or winding leg 7 in uniform layers to form the coil, it is wound on in a random fashion with no effort being made to lay the wire in a precise pattern. This results in many cross overs and points of Contact between the various turns of the winding and it also results in more pressure at the points of contact than occur in a form wound coil. Also, there is a greater potential or voltage dillerence between many of the adjacent and crossed turns than there is between adjacent turns in a precision wound wiring. All of this, the cross overs, the higher pressure, and the higher potential between turns, is of aid in accelerating an initial failure in the winding before the outer covering lil can melt. ln other words, if a small failure should occur within the winding, the numerous contacts between the turns of the winding and the pressure between the turns tends to cause a quicker failure of the coil and thereby aids in the interruption of the line current by the line use before the covering lil can fail. lt will be understood that the acceleration of any failure within the winding is a very important feature of this invention since for t motor to fail safe the line fuse must be opened or the wire of the winding ruptured (melted apart) before the outer covering lil can be melted. The covering liti will maintain flame, sparks and any molten metal within the winding 6 provided the failure occurs quickly, but obviously if the failure were to occur over a long period, the covering itself might fail. Thus, it is important to this aspect of my invention that the magnet wire of the winding have a predictable melting or failure point appreciably lower than the internal temperature of the winding at which the material of the outer covering lil will melt, and it is also very desirable that the coil be random wound to aid in accelerating the failure.

lt is also important that the lead-in connections for the winding 6 be such that water cannot get into the winding through them. ln addition, they should not provide a path for llame or sparks to escape from the winding in the event of failure. T he manner which this type of lead-in connection is obtained in the illustrated embodiment is best shown in FGS. l and 3. As is there shown, a pair of identical slots l2 are provi-:led at the opnosite ends of the winding or yoke i for accom dating the lead-in wires. The walls of these slots are covered by the integral insulation layer ll oi the winding leg and the lead-in conductors i3 and le for the winding re extended into the respective slots. As is shown in PEG. 3 for thc conductor t3, the ends of the lead-in condoctors are bai-ed Within the slots l?. and the opposite ends of the magnet wire forming the coil o are brought into the respective slots and connected to the eared ends of the lead-in conductors. The connection l5 between conductor i3 and the one end of the winding 6 is shown in lFG. 3, and it will be understood that an identical connection is made in the other slot l2 between the conductor ad and the other end of the winding.

After the connections are made between the lead-in conductors and the ends of the winding o, the magnet wire ends having been bared of insulation for that pose, the slots l2 are then iilled with a suitable insulating iiller material. Any suitable llame and moisture resistant material may be used and in the illustrated embodiment an epoxy resin is employed. Then when the outer covering lil of the coil 6 is formed, the ends of the covering are extended over the opposite ends of the slots l2 so as to iiow around the lead-in conductor on one side and around the wire extending into the winding on the other end. The extension ld of the covering l@ over the leadin conductor 13 may be readily seen in FGS. l and 3 and it will be understood that the magnet wire leading into the winding is likewise covered by the covering l@ on the other end of the slot. Also, it will be understood that in the illustrated embodiment, an identical arrangement is used for the other lead-in conductor ld at the other end of the winding leg. With the covering lil extending around and bonded to both ends of the winding and the lead-in conductors, thereby the lead-in connections are both moisture proof and llame proof. *Y

To insure the effectiveness of the joint, however, the lead wire insulation itself must be water impervious and must be compatible with the material forming the covering l0. ln other words, the lead-in wire insulation must be such that the covering material can readily be bound to it and also its constituents must be such that it will not attack the covering lil, or vice versa, over a long eriod of time.

It will thus be seen that the covering l@ is defective to prevent the entry of moisture into the winding during operation and is also eifective to maintain any flame etc. within the winding in the event of failure since due to the characteristics of the magnet wire insulation, the failure will be accelerated so as to open the line fuse or the winding itself before the covering il@ melts. It will, of course, be obvious that the motor is preferably used with a suitable fuse or breaker in the energizing circuit. But since the winding will itself melt open before the covering il@ fails, the motor can be used without an individual fuse, for example, in packaged air conditioning units where only one relatively large fuse or breaker is included to protect all the components.

The outer covering also prevents the entry of water into the winding, and preferably this water resistant characteristic is aided by the provision of a Ilayer of varnish over the coil after the covering it) is formed. In other word-s, the winding leg and coil are preferably given a varnish treatment and the resultant varnish layer assists in keeping moisture out of the winding.

My improved arrangement of the motor winding thus allows the elimination of an over-all metallic motor casing insofar as the protection of the windings is concerned. However, if the expense and other disadvantages of a motor casing are to be avoided, the bearing and lubrication system of the motor must also be constructed so that there is no need for an over-all housing. In addition, the lubrication system should provide for reliable bearing life over a long period of years with a minimum of maintenance, i.e., reoiling, being required. To this end, I have provided a new and improved bearing assembly in the motor l, now being covered by my aforementioned divisional application, which is particularly advantageous for use with my winding arrangement although it does have utility independent of the Winding arrangement, and vice versa.

Referring now to FIGS. 1, 2 and 4, it will be noted that the rotor 3 is mounted on an output shaft ll'. This shaft is supported at opposite sides of the rotor by identical bearing assemblies 18 the only difference between the two assemblies being that the right hand one (as viewed in FIG. 2) includes an open end cap instead of a closed end cap to accommodate the output shaft eX- tension. Each of the bearing assemblies l includes a `central bearing member 19 formed of relatively porous sintered material, and these members 19 journal the shaft 1.7 for rotation. The respecitve bearing members were supported from the stator 2 by means of suitable end brackets or frame members Ztl and 2l as best shown in FIG. 2. The end brackets are generally U-shaped in configuration with the legs of the U being attached to the stator and with the bight or center portion of the U supporting the associated bearing 1.9. In particular, the bearings extend through suitable openings 22 provided at the center of the brackets and are staked thereto as is best shown at 23. This staking is done under considerable pressure and forms a permanent mount of the bearing 19 on its respective end bracket. The end brackets may be attached to the stator in any suitable means as by cementing.

In order to lubricate the bearings 19, each of the bearing assemblies 1S includes a suitable lubricant reservoir or pad 2.4 which is impregnated with a suitable grade of lubricating oil. In the illustrated embodiment, the lubricant pads Zd are disposed around the bearings l@ and in each assembly a region of `contact 25 is provided between the pad and the bearing around the entire peripheral surface of the bearing. During operation, the lubricant in the pad slowly seeps from the pad through this region of contact into the bearing l@ and thence through the shaft Ii' to lubricate it. lt will be understood that this seepage occurs at a very slow rate, for example, at a rate in the neighborhood of one tenth of a cubic centermeter per thousand hours of operation.

To protect the reservoir pad and to prevent the evaporation of lubricant, it is enclosed in each of the assemblies l within a substantially imperforate casing or housing 26 which is formed of a main dish shaped casing member 27 and a cooperating cover 28. The casing 2:7 and the cover 28 may be attached together by any suitable means after the pad 24 is placed therein but preferably they are cemented together as indicated at 28a, the cementing material extending all the way around the cover to provide a good seal. lt will be noted that the inner end of the cover member 28 rests on and is cemented to a stepped end cap 29, or 29a in the case of the left hand assembly. The only difference between the end cap 29 and the end cap 29a is that the end cap 29 includes an opening accommodating the shaft ll'i whereas the end cap 29a is closed. As will now be explained, these end caps 29 and 29a serve as the main mounting members for the motor, they being arranged as illustrated in FIG. 2 to accommodate resilient mounting rings il@ which may be attached to any suitable support.

So that they may eifectively support the motor, the inner ends of the end caps Z9 and 29a are extended over the outboard ends of their respective bearings l@ as is best indicated at 3l in FIG. 4. They thus provide a firm support for the bearings from the mounting rings 30. The bearings 19 in turn support both the rotor shaft and the stator, the rotor shaft being carried directly and the stator being mounted thereon by the brackets 2li and 22. To provide proper spacing, the end caps 29 and 29a are stepped as indicated at 32 and a spacer 33 is positioned between the end of the respective bearing and the step so as to obtain the proper positioning of the end cap relative to the bearing. ln other Words, the end of each end cap must fit over the outer end of its associated bearing in order to support the motor, but must not lit so far over the bearing as to interfere with the iow of lubricant from the pad 2d to the bearing.V This mounting arrangement is very desirable because it results in the motor being supported as close as possible to the yshaft center line. Thereby a high degree of vibration isolation is obtained with a minimum of parts.

Each of the housings 26 comprising the main casing member 27, the cover member 23 and the bearing cap 29 or 29a forms a generally imperforate structure around the associated lubricant reservoir pad 2d. This, or course, prevents moisture from seeping into the pad and also prevents evaporation of the lubricant from the pad. However, it is desirable for effective oiling of the associated bearing for long periods of time that an opening be provided in the casing so that the same air pressure is maintained inside the casing as outside. If no opening were provided in the casing, obviously either a pressure build up or a pressure reduction could occur within the housing depending upon the ambient temperature and the temperature of operation, which might cause the oil to seep through the bearing either faster or slower than is desired. In other words, the effective oiling of the bearing might be interfered with over a period ot time. Thereby, l have provided a breather opening 34 in the cover member 2b of each bearing assembly. This breather opening allows air to enter and leave the interior oi the casing and thereby keeps the air pressure within the casing the same as that of the surrounding environment. Also formed on the cover member 2d are a plurality of longitudinally extending inwardly protruding ribs 35. As is best shown in FlG. 4, these ribs 35 space the lubricant pad 34 slightly from the cover member. In other words, they cause a space 36 to be left within the casing 26 between the lubricant pad 24 and the cover. This space is desirable since drops or beads of oil may very well occur on the exterior of the pad during the initial period of its operation. In other words, particularly when the motor is irst put into service, drops of oil may appear on the surface of the saturated pad as the motor heats up. Also, drops of oil may be carried out of the pad by bubbles of air leaving the pad due to pressure changes. The space 36 between the cover member and the pad accommodates these drops of oil and allows them to run from an oversaturated portieri of the pad to a drier portion of the pad which then reabsorbs it. Thus, no oil is lost during service, but rather, even though the drops appear, the oil is retained for future use.

With the possibility of oil drops appearing in the space 36, it is of course, very desirable that these drops not be allowed to escape through the breather opening 34. Thus, for this reason, an inwardly extending tlange 37 is provided around the breather opening, extending into the space 36. This tlange 37 is high enough that it eX- tends almost to the surface oi the pad 24, and thereby any oil drops leaking from the pad in the space 55 will run down the pad and cannot escape through the bleeder opening 341;.

it will be noted that in each of the assemblies i3, the bearing housing Z6 is arranged to prevent leakage of the oil at the ends of the bearing itself. At the outboard end of the bearing, the end caps tend to prevent the loss of oil from the bearing. The end cap 29a is, of course, closed and the end cap 29, although open to allow the escape of the shaft, is so extended that oil seeping out the outboard end of the associated bearing i9 merely falls onto the shaft rather than escaping from the motor. The cover 28 is irrnly cemented to the ilange 31S of the bearing cap as indicated at $9 so that an oil tight seal is provided preventing leakage between the cover and the end cap. At the inboard end of the respective bearings, the brackets are staked rrnly thereto so that very little oil can pass by them and also the members Z7 of the casing are cemented iirmly to the bracket as indicated at il so that oil cannot escape between the brackets and the bearing assembly casings. Thereby, very little it any of the lubricant can escape at the inboard end of the bearings.

Preferably, and as shown a circular rib il is formed on the casing member 27 to prevent the cement 33 from leaking into the inboard end of the bearing during assembly.

Thus, it will be seen that l have provided a bearing assembly which does not require an over-all casing for the motor but yet is elective to provide reliable service over an extended period of years with no reoiling or other maintenance being required. ln fact, with the lubricant pad 24 of the assembly being completely protected from the surrounding atmosphere except for the one bleed hole,

l@ the bearing assemblies will operate reliably in extremely moist atmospheres.

Considering all of the above, it will be seen that l have provided a new and improved motor which may be used for applications requiring enclosed electrical components but yet does not require an over-all motor casing or housing. With t re motor being open to the surrounding atmosphere it, of course, ventilates itself and so that the heat generated in the windings is readily dissipated. Therefore, the adverse temperature conditions affecting the insulation life and the lubricant properties in the ordinary totally enclosed motor are not present in my improved motor, and also the motor is much smaller in size than a comparable totally enclosed motor of the same rating. in addition, due to the elimination of the motor s iell and other special parts the motor is much less expensive to manufacture than a totally enclosed motor of equivalent rating.

While in accordance with the patent statutes, I have described what at present is considered to be the preerred embodiment of my invention, it will be obvious to those skilled in the art that numerous changes and modiications may be made therein without departing from the invention and it is therefore aimed in the appended claims to cover all such equivalent variations as fall within the true spirit and scope ofthe invention.

What l claim as new and desire to secure by Letters Patent of the United States is:

i. A dynamoelectric machine for service where enclosed electrical components are desired, comprising a rotor, a stator, an excitation winding mounted on said stator, said winding being formed of a number of turns of metallic wire having an adherent coating of resinous insulating material, said winding being random wound so there are cross overs between the various turns of said winding with the turns being in contiguous engaging relation, and an imperorate covering oi resinous material formed over the exposed outer surface of said winding in a generally non-penetrating relation thereof, said covering being effective to resist melting at internal hot spot winding temperatures high enough to melt said wire coating, whereby in the event of a failure in said winding said wire coating is melted on more than one contiguous turn to accelerate a complete failure of said motor before said covering on said winding is ailectod.

2. An electric motor for service Where enclosed electrical components are desired, comprising a rotor, a stator including a yoke section, said yoke section having a pair of slots therein and further having a layer of resinous insulating material formed thereon, said layer of resinous material covering said yole section including the walls of said slots, an energizing winding mounted on said yoke section over said layer of insulating material, said winding being formed of a number of turns of metallic wire having an adherent coating of resinous insulating material, a pair of external leads for energizing said winding, said leads and the opposite ends of said wire forming said winding extending respectively into said slots and being electrically connected therein, a body of insulating material in each of said slots covering the connections between said leads and the ends of said winding, and an imperforate covering formed over said winding and said slots and bonded to said layer of insulating material on said yoke and said external leads, said covering being efective to resist melting at internal hot spot winding ternperatures high enough to melt said wire coating, and an integral layer of insulating varnish formed over said yoke and said covering of said winding to aid in rendering said motor moisture proof.

3. The dynamoelectric machi -e of claim l in which the stator includes a yoke section having a layer of resinous insulating material formed directly on the yoke section between the section and winding, and said imperioi 1 12 rate covering of resinous material being bonded to said 2,836,740 5/58 Gibson et al. 310-4-5 layer to enclose said winding. 2,845,552 7/58 Robinson 310-90 2,847,593 8/58 Selbach et a1. 310-90 References Ce by the Examiner k2,922,902 1/60 Hargreaves 3G-45 r 2,947,893 8/ 60 Bussone 310-90 UNITED STATES PATENTS o 3,037,822 6/62 Plummer 31o-90 1,249,770 12/17 Kempton 310-43 X 2,095,705 10/37 Kassier 31o- 43 X FOREIGN PATENTS 2,340,905 2/44 Sigmund et al. 310-88 1,148,642 6/57 France. 2,548,133 4/51 Treat 310-43 10 x 2,611,939 9 /52 Hm et aL 310 45 MILTON O. HIRSHFIELD, Przmary Examiner. 2,822,483 2/58 De Jean et al. S10-45 CRIS L, RADER, Examiner- 

1. A DYNAMOELECTRIC MACHINE FOR SERVICE WHERE ENCLOSED ELECTRICAL COMPONENTS ARE DESIRED, COMPRISING A ROTOR, A STATOR, AN EXCITATION WINDING MOUNTED ON SAID STATOR, SAID WINDING BEING FORMED OF A NUMBER OF TURNS OF METALLIC WIRE HAVING AN ADHERENT COATING OF RESINOUS INSULATING MATERIAL, SAID WINDING BEING RANDOM WOUND SO THERE ARE CROSS OVERS BETWEEN THE VARIOUS TURNS OF SAID WINDING WITH THE TURNS BEING IN CONTIGUOUS ENGAGING RELATION, AND AN IMPERFORATE COVERING OF RESINOUS MATERIAL 